Reinforced plastic container with an integral heating element

ABSTRACT

A plastic reinforced fiberglass container has heating element integrally bonded into the container&#39;s interlaminate structure and preferably between the corrosion liner and the structural lamina to permit efficient heating of the container contents. A thermocouple is also embedded in the interlaminate structure and preferably positioned at the same location to achieve sensitive temperature control of the container&#39;s contents.

This is a division, of application Ser. No. 06/034,775, filed Apr. 30,1979 now U.S. Pat. No. 4,287,663.

BACKGROUND

The invention relates generally to reinforced plastic containers andmore specifically to a reinforced plastic container with a heatingelement integrally bonded in the container's interlaminate structure andthe method of making the same. The invention will be disclosed, by wayof example, in connection with a reinforced fiberglass tank of the typecommonly used in the chemical and food processing industries. The tankof the preferred embodiment has a heating element integrally bondedbetween a corrosion barrier and a support layer or lamina in thecomposite laminate structure. The invention, however, relates moregenerally to containers and may be used for other types of containers,as for example fiberglass pipe, with integrally formed heating means.

The conventional method used in the past for heating fiberglasscontainers, as for example fiberglass tanks, has been to externally wrapa heating tape, of either polyester or TEFLON (TEFLON is a trademark ofthe E. I. DuPont Company of Wilmington, Delaware forpolytetrafluoroethylene) containing an electrical resistance heatingelement, about the periphery of the container. When energized, theheating elements were operative to transfer heat to the container'scontents, but only after transferring the heat through the thermalresistance of the entire container wall.

Another method of heating container contents has been to externally wrapan electrical heating blanket, usually formed of fiberglass or silicone,and to heat the container contents by again energizing the heatingelements. In addition to the disadvantage of being required to transferthe heat through the container wall prior to heating the containercontents, heating blankets are frequently difficult to apply or to wraparound a container.

Further difficulties with externally applied heating elements haveresulted from nozzles or drains which are fastened onto containers asaccessories and which interfere with the wrapped heating elements.

Additionally, many tanks are used outdoors and are frequently theobjects of vandalism. When subjected to flying projectiles, as forexample rocks and bullets, the externally applied heating systemsexperience failure. Often, damage to heating elements, which areoccasionally covered by insulation on the peripheral sidewalls of thetank, necessitated the removal of all of the insulation material and thereplacement of the entire heating system.

Secondary layups have also been used to apply heating elements to tanks.A heating element was placed or overlayed upon a surface of an otherwisecompleted or used tank and covered with resin in an attempt to cover theheating element and to secure it to the container. This overlaying, evenwhen placed on the inside of the tank, resulted in a number ofdisadvantages. First, the new surface which was necessitated to coverthe heating element was not molded. Thus, the resulting surface was notsmooth and had diminish cleanability as compared to a molded surface.This last mentioned consequence takes special significance forcontainers used in certain industries, as for example the food industry,where even small imperfections in the surface may substantially increasethe possibility of bacteria buildup. Further, secondary layups areinherently more difficult to bond and a real and active danger existsthat the secondary layup will experience laminate shear or separationfrom the primary surface.

In the past, the disadvantages noted above were tolerated for lack of abetter alternative. Applicant, however, has discovered a new and novelmethod of forming a reinforced plastic fiberglass container with anintegral heating means that overcomes the disadvantages of the priorart. A heating element, according to the present invention, can now beplaced in a container's interlaminate structure without deparating andwithout deleteriously affecting the physical properties andcharacteristics of the resulting structure.

Accordingly, it is an object of the present invention to provide amethod of forming a fiberglass container with an internal molded surfaceadapted to interface with the container contents and having a heatingelement integrally formed in the container's interlaminate structure.

It is a further object of the present invention to provide a method offorming a fiberglass container in which a heating element is intimatelypositioned with respect to the contents to be heated.

It is another object of the present invention to provide a method offorming a heated fiberglass container which is energy efficient.

It is yet another object of the present invention to provide a method offorming a fiberglass container with a heating element formed in theinterlaminate structure which does not reduce the structure's physicalstrength characteristics.

It is still another object of the present invention to provide a methodof forming a fiberglass container with heating means which are guardedagainst vandalism.

It is still another object of the present invention to provide a methodof forming a heating element which is bonded between a corrosion barrierand a structural layer of a container.

It is yet another object of the present invention to provide a method offorming a fiberglass container with high heating capabilities whichcannot be damaged by overheating.

It is yet another object of the present invention to provide a method offorming a container with heating elements which do not interfere withauxiliary nozzles, drains, etc.

It is still another object of the present invention to provide a methodof forming a container which permits accurate temperature measurementand control of the container contents.

SUMMARY OF THE INVENTION

In accordance with the invention, a mold is covered with a reinforcedplastic material. An electrical resistance heating element encapsulatedin a plastic material compatible to the reinforced plastic covering isthen placed on the covered mold. After the encapsulated resistanceheater is secured to the plastic covered mold, a further covering ofplastic reinforced material is applied to the covered mold and bonded tothe encapsulated resistance heating element and to the reinforcedplastic material which was applied prior to the placement of theencapsulated electrical heating element.

In the most preferred form, the invention provides a reinforced plasticfiberglass container with a relatively thin chemical and corrosionresistant molded barrier supported by a structural layer which isintegrally bonded to the corrosion barrier. An electrical resistanceheating element is sandwiched between the corrosion barrier andstructural layer and bonded integrally to both the corrosion barrier andthe structural layer in a manner which eliminates any reduction in thephysical strength of the composite laminate structure.

The container is preferably formed by covering a mold with a veil ofchemical and corrosion resistant grade of fiberglass and thereaftercovering the veil with a backup layer of chop glass, resin and acatalyst for inducing an exothermic chemical reaction which allowsmolecular cross-linking to take place to form a corrosion barrier. Afterpermitting the corrosion veil and the backup layer to harden, anelectrical resistance heating element encapsulated in E-grade fiberglassis placed on the hardened corrosion barrier and preferably covered withresin. A structural support layer or lamina including a layer of choppedfiberglass, resin and a catalyst is then applied to the corrosionbarrier and encapsulated heating element and this structural layer isintegrally bonded to the corrosion barrier, sandwiching the heatingelement between the corrosion barrier and the structural lamina.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects and advantages of the invention will become apparent uponreading the following detailed description and upon reference to thedrawings, in which:

FIG. 1 is a schematic depiction of a mold covered with a thin film ofchemical and corrosion resistant fiberglass and resin.

FIG. 2 is a schematic depiction of resin on the mold of FIG. 1 beingrolled to a uniform thickness.

FIG. 3 is a schematic depiction of a spray gun spraying a backup layerof strands of fiberglass, resin and a catalyst onto the covered mold ofFIG. 2.

FIG. 4 is a plan view of a piece of braided electrical resistanceheating wire encapsulated in E-grade fiberglass.

FIG. 5 is a schematic view depicting placement of the encapsulated wireof FIG. 4 onto the covered mold of FIG. 2.

FIG. 6 is a schematic depiction of resin being applied to bond theencapsulated wire of FIGS. 4 and 5 onto the backup layer of FIG. 3.

FIG. 7 is a schematic depiction illustrating the application of amixture of fiberglass, resin and catalyst to the cover mold of FIG. 5.

FIG. 8 is a perspective view of a a portion of a fiberglass reinforcedplastic tank which has been made according to the present invention.

While the invention will be described in conjunction with a preferredembodiment and procedure, it will be understood that it is not intendedto limit the invention to that embodiment or procedure. On the contrary,it is intended to cover all alternatives, modifications and equivalentsas may be included within the spirit and scope of the invention asdefined by the appended claims.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

A conventional fiberglass reinforced plastic tank or other type ofcontainer commonly has walls formed of a chemical or corrosion barrierand a structural or support layer which is integrally bonded to thatcorrosion barrier. The corrosion barrier is generally relatively thin,approximately 120 mils in thickness, and is generally formed of twoparts. The first part is very thin, approximately 10 to 20 mils inthickness, and is formed of C-grade fiberglass or the equivalent. ThisC-grade fiberglass most commonly, although not always, comes in a sheetform which is rolled up similar to a roll of paper. The C-gradefiberglass sheet is actually a multitude of tiny chopped fibers that areheld together by a binder and is commonly referred to as a C-veil.

Referring now to the drawings, FIG. 1 depicts a mandrel or mold 10 whichis covered by a C-veil 12 which is in turn covered by a layer of aresin, a polyester resin in the preferred embodiment. As should beapparent from the illustration of FIGS. 1-3 and 5-7, the mandrel or moldhas a container-shaped configuration which is specifically shown as atank configuration. In its intended use, the bottom of a containerformed on the mold will correspond to the top of the mold. Although notcompletely necessary, it is preferable to wet down the mold with resinprior to covering it with the C-veil. The C-veil sheets are then wrappedaround the resin wetted mold to completely cover it. Several sheets aregenerally required with a specially cut piece of a veil used to coverthe top of the mold (which will ultimately be at the bottom of the tankin the illustrated embodiment). The sheets are overlapped slightly attheir junctions to insure that the veil completely covers the mold.After completely covering the mold with the C-veil 12, the veil 12 iscompletely covered with resin. This resin, together with the resin whichwas initially applied to the mold, soaks into the C-veil 12 until theveil is saturated. Although, applying the resin only to the backside ofthe veil after the veil is placed on the mold would suffice, the initialcoating of resin assists in soaking the veil from both sides. Further,the initial resin application serves to eliminate trapped air beneaththe veil and thus is preferable in forming the liner, a critical part ofthe container.

As illustrated in FIG. 2, this resin covering is rolled out thoroughlywith a roller 14 to once again remove any trapped air and to make theresin covering of uniform thickness. As noted above, the resin used inthe preferred embodiment is a polyester resin, most specifically abisphenol-A fumarate polyester resin. The particular resin used must bechemically compatible with the binder which holds the chopped fibers ofthe C-veil together. In the preferred embodiment the binder used forthis purpose is silane. As will be apparent to those skilled in the art,however, different types of resins, as for example vinyl or epoxyresins, may be used in forming the tank. It is important, however, thatthe resin which is chosen be compatible with any binders which are usedin any fiberglass veils or mats. However, since these limitations arewell known in the art and form no part per se of the present invention,no further reference thereto will be made.

FIG. 3 depicts a spray or chopper gun 16 applying a mixture 18 ofchopped glass, resin and a catalyst onto the now uniform surface of FIG.2. This step immediately follows the rolling step illustrated in FIG. 2and takes place before the resin is permitted to dry. The contents ofthis layer of material applied to the container, the chopped glass,resin and catalyst, is commonly referred to as the backup layer and theamount applied is carefully controlled. The backup layer is thencarefully rolled out to completely cover the previous layers in auniform thickness. The amount of backup material supplied is such thatwhen uniformly rolled out with roller 14, it generally has a thicknessof approximately 100 to 110 mils. This thickness may vary, however, anda thicker layer may be preferable in certain situations. Again, as thoseskilled in the art will readily appreciate, the catalyst serves toinduce a chemical reaction between the C-veil and the backup layer. Inthe preferred embodiment, a solution (between 30 percent and 60 percent)of methyl ethyl ketone peroxide sold under the trademark LUPERSOL DDM(sold by Lucidol Division of Pennwalt Corporation) is used. Othercatalysts are well known in the art, however, and other catalystscompatible with the selected resin may be used.

After being carefully rolled out to a uniform thickness, the backuplayer and C-veil are permitted to undergo an exothermic reaction (inwhich the tank temperature may reach approximately 320° F.) in whichmolecular cross linking between the various components thus far appliedtakes place. This reaction, which was prompted by the catalyst, isirreversible and the plastic becomes thermoset. Once the backup layer ispermitted to cool, the corrosion barrier or layer of the container iscomplete. This reaction, in fact, defines the limits of the corrosionbarrier.

Again, it would be appreciated by those skilled in the art, that thebackup layer may be applied in different forms, as for example afiberglass mat formed of chopped glass fiber held together by a binder.A mat comparable to the 100 mil covering applied by the chopper gunwould be a 11/2 ounce per square foot mat of the type which iscommercially available. If a mat form of backup were used, the catalystwould preferably be mixed with resin and applied to the mat by a brush.Regardless of the form, however, the backup layer is preferably E-gradefiberglass.

FIG. 4 depicts a strip of an electrical resistance heating element 20.The electrical wire 22 of the strip 20 transverses and winds about in aserpentine fashion as it is supported by a plurality of elongatedfiberglass strands 24 formed of E-grade fiberglass. The electrical wire22 is also embedded in E-grade fiberglass.

As schematically illustrated in FIG. 5, the encapsulated wire 22 and theheating element 20 shown in FIG. 4 is placed on the bottom (shown on topof the mold--this will, however, be the bottom of the tank in use) ofthe container adjacent to the backup portion of the corrosion barrier.In the illustrated construction, the heating element 20 is placed in acontinuously decreasing circular or spiral arrangement on the tankbottom. Leads 26 from each end of the heating element are groupedtogether in a bundle and placed to continue along the tank sidewalls inthe specifically illustrated arrangement. In the preferred construction,a thermocouple 28 is also placed at this level of the laminate structurein such a position as not to touch the heating element 20, the leadsfrom the thermocouple being bundled with the lead wires from each end ofthe heating element. If more than one segment of heating element 20 isused, as may be the case for a large container, each segment 20 ispreferably wired in parallel.

Once the heating element 20 and thermocouple 28 are in place, resin isapplied to cover these elements and to hold them in place adjacent tothe surface of the corrosion barrier as shown in FIG. 6 when the resinis applied with a brush 30. Preferably, this resin is rolled out to auniform thickness with a roller 14 in a manner similar to that shown inFIG. 2. Additionally, as before, the rolling action also tends to removeany trapped air which would cause voids and reduce efficiency.

Once the heating element 20 and thermocouple 28 are secured in place,the container's structural layer may then be applied. The exact form ofthe structural layer may vary depending upon the application for whichthe particular container is designed. For example, a small tank or pipemay have a structural layer of only chopped glass, resin and catalyst ofapproximately 100 mils in thickness. FIG. 7 depicts such a structurallayer of chopped glass, resin and catalyst mixture 32 being sprayed ontothe liner and heating element in a manner similar to that illustrated inFIG. 3. This layer of material would also be rolled out to a uniformthickness with a roller as illustrated in FIG. 2.

Other types of structural layers are possible and would be preferable insome applications. For example, it may be desirable to wrap strips ofcontinuous filament winding, continuous filaments of glass which arewrapped around lines, about the sidewalls of a tank for purposes ofreinforcement. This type of reinforcement provides a very high tensilestrength. For a large tank, it would be desirable to reinforce thestructure with woven roving, a continuous strand of glass that is wovenin two directions, to provide reinforcement in each direction. Wheneither continuous filament winding or woven roving are used, they aregenerally wrapped around the liner and chopped glass, resin and catalystis sprayed over these reinforcements in a manner analogous to thosepreviously described.

FIG. 8 shows a a portion of the finished fiberglass reinforced plastictank formed in the steps illustrated in FIGS. 1-3 and 4-7 with a controlbox 36. The wiring leads 26 to the heating elements of the preferredtank extend from the bottom and up the tank sides to a predeterminedlocation at which the control box is mounted. With the exception of thewire ends which are bundled up and protected, the lead wires 26 from theheating surface to the control box location are covered by thestructural layer when it was applied. Thus, the lead wires 26, like theheating elements 20 and the thermocouple 28, are sandwiched between thecorrosion liner and the structural layer in the interlaminate wallstructure. The ends of the lead wires 26, however, extend through thestructural lamina for connection to the control box 36.

The controls 38 (The controls are conventional and not specificallyillustrated) of the preferred embodiment are also mounted the controlbox 36 in a fiberglass enclosure and this enclosure is laminated to thestructural layer of the container. As seen in FIG. 8, mats 40 offiberglass are placed on each of the control enclosure's sidewalls 42and extend continuously onto the tank surface 44. Resin is then appliedto the mats to bond them to both the tank and the control enclosure.

Once the control enclosure is mounted, a mixture of resin and paraffinwax is applied to the exterior of the container to cover the structurewith an air inhibiting coating. This wax and resin mixture, which mayalso contain a pigment to color the container, permits final curing ofthe structural layer. The controls 38 are then placed inside the controlenclosure and connected to the heating elements 20 and thermocouple 28as well as an external power supply, the leads to the external powersupply being contained in an external conduit 46.

The present invention thus provides both a fiberglass container having amolded surface adapted to interfere with the container contents and anintegral heating means. The application of reinforced plastic materialto a mold is interrupted and an electrical resistance heating element,encapsulated in a plastic material which is bondable to the reinforcedplastic material, is secured to the initially applied material. Afurther covering of plastic reinforced material is then applied to coverthe mold. This further covering is bonded to the first appliedreinforced plastic material and to the encapsulated heating element. Inthe preferred form, the heating element is sandwiched between thecorrosion layer or liner (whose limits are defined by an exothermicchemical reaction) and a support structure which is heated to the liner.As such, the heating element becomes a part of the container itself.

Moreover, the heating element is intimately positioned with respect tothe container contents. It is separated in the illustrated form only bythe relatively thin corrosion liner. The significance of this proximityto the container contents is that the thermal resistance between theheating elements and the contents to be heated is significantly reduced.The energy required to transfer a predetermined quantity of heat iscorrespondingly reduced. This placement of the heating elements avoidsthe thermal resistance of the structural layer of the container. Sincefiberglass has a thermal resistance approximately 200 times that ofsteel, the difference in thermal resistance becomes significant. Also,the container contents are much more responsive to temperature changesinitiated by the heating elements as the transient heat transfercharacteristics of the heating system is greatly improved.

Due to the high thermal resistance of a fiberglass container'sstructural layer, the watt density of heating elements used in the pasthas been sufficiently high to damage fiberglass, particularly when theheat sink provided by the container contents ceased to interface withthe portion of the container structure opposite the heating element.This situation frequently occurred when the heating elements were placedon the side of a tank and a fluid level inside the tank was loweredbeneath the level of the heating element. The watt density of thepresent invention's heating element sandwiched between the liner andcorrosion layers may be reduced to a level which will not cause thedegradation of the fiberglass, even when the container is completelyempty. Furthermore, this watt density may be lowered while stillmaintaining the heating capability of prior heating elements withdangerously high watt densities externally applied to the structurallayer.

The present invention also lends itself to improved temperature controlof a container contents while still avoiding any possibility ofcontamination. Since the thermocouple sensing means is also intimatelypositioned with respect to the container contents, the sensedtemperature of that location is very nearly the same as the containercontents.

Physical tests performed on a laminated fiberglass structure constructedaccording to the method presented in the preferred embodiment has shownthat virtually no difference exists between the structure with anintegral heating means and a comparable fiberglass laminate without suchheating means. These tests included tensile tests, compression tests,and flexual tests.

The heating elements in the preferred embodiment were placed exclusivelyon the tank bottom. Applicant has found that the present invention isparticularly well suited for such placement. Placement on the bottom ofa container permits heating of the entirety of the contents due tonatural convection currents and frees the sidewalls of the container forother uses without interfering with auxiliary drains, nozzles, etc. Theinvention is quite applicable for use on container sidewalls however,and it may be advantageous to place heating elements in theinterlaminate structure of a container sidewall between the corrosionliner and the structural member in the same manner as described abovefor the container bottom.

Thus, it is apparent that there has been provided, in accordance withthe invention, a method and apparatus that fully satisfies the objects,aims, and advantages set forth above. While the invention has beendescribed in conjunction with a specific embodiment thereof, it isevident that many alternatives, modifications, and variations will beapparent to those skilled in the art in light of the foregoingdescription. Accordingly, it is intended to embrace all suchalternatives, modifications, and variations as fall within the spiritand broad scope of the appended claims.

What is claimed is:
 1. A plastic fiberglass reinforced container withintegral heating means, comprising:(a) a corrosion liner, said corrosionliner including:(i) a continuous molded internal surface of C-gradefiberglass, said molded surface being adapted to interface with thecontainer contents; and (ii) a backup layer of E-grade fiberglass bondedto said C-grade fiberglass; (b) a structural lamina of E-gradefiberglass bonded to said backup layer; (c) an electrical heatingelement encapsulated in E-grade fiberglass positioned between saidcorrosion liner and said structural lamina, said heating element beingbonded to both the corrosion liner and the structural lamina and beingadapted to heat the container contents; and (d) electrical lead wiresextending through said structural lamina and being adapted to connectsaid heating element to an external electrical power source.
 2. Acontainer as recited in claim 1 further including a thermocoupleembedded within the laminate structure.
 3. A container as recited inclaim 2 further wherein said thermocouple is positioned between saidcorrosion liner and said structural lamina.